DE1597844C3 - Process for the reverse development of an electrostatic charge image - Google Patents

Description

The invention relates to a method for reverse development of an electrostatic charge image a photoconductive layer using a liquid developer, wherein by applying a external voltage to a development electrode, the electric field in the range of the maximum charge density the photoconductive layer just compensated or with a slightly lower voltage than that for Compensation required voltage is applied to the development electrode.

In the electrophotographic process, a toner is made to adhere to the areas which electrostatic charges are present and which have no electrostatic charges available. The latter method of operation is referred to as the "reverse development process".

In the reversal development method, a photosensitive material is used which has a electrically conductive support and a photoconductive layer, e.g. B. from amorphous selenium or one Mixture of zinc oxide powder and a resin is used. The photoconductive layer is more suitable Way, for example by a corona discharge in a dark room, uniformly charged, and then subjected to an image exposure, whereby the electrical charges on the exposed, photoconductive Layer neutralized and eliminated, while the electrical charges on the remaining areas lag behind. Accordingly, the electrostatic charges appear on the photoconductive layer of an image, according to the photograph in appearance. When a toner of the same charge type as the electrical charges on the photoconductive layer is brought into contact with it, it adheres to the charge-free areas.

A method of reverse development of a static charge image on a photoconductive layer using a liquid developer is described, for example, in US Pat. No. 3,176,653.

In the known inversion method, an outer electrode is used on which an outer electrode Voltage is applied to compensate for the charges present on the photoconductive layer, reverse charges being generated in the charge-free areas of the photoconductive layer. Included the voltage applied to the outer electrode can be at most so high that it removes the charges of the photoconductive layer fully compensated, but it can also be less, so that only one Attenuation of the charges present on the photoconductive layer id takes place, but im charge-free area charges of opposite signs are induced.

When this method of operation is carried out, however, there is the disadvantage that overcompensation may occur takes place by the external stress field, z. B. in the areas to be discharged, a reverse charge is introduced, which is due to the dark decay of the photoconductive layer.

The object of the invention is therefore to create a method of the type mentioned at the outset, in which fog caused by undesirable toner deposition due to the dark decay of the photoconductive Material in the liquid can be effectively prevented.

This object is achieved according to the invention in that the external voltage is changed during development in accordance with the dark decrease in the charge of the photoconductive layer in contact with the liquid developer.
According to one embodiment of the invention, the voltage change can be carried out continuously and synchronously with the dark decay.

The voltage change can also take place in one step.

The invention is explained in more detail below with reference to the drawing.

Fig. 1 illustrates the distribution of an electric field on the photoconductive layer in the electrophotographic process.
• »ο Fig.2 illustrates the effect of a nearby electrode that is used to prevent the edge or edge effect.

Fig.3 explains the application of a voltage to the Electrode of Fig. 2.

- ^ Fig. 4 shows the dark decay in a graph the charged photoconductive layer and

Fig. 5 is a graph showing the dark decay in dem'Fall when the photoconductive charged layer to stand for a short time in air and then ^r> "is immersed in an insulating liquid.

In FIG. 1, sketch (a) explains the direction and distribution of electrical lines of force in a sectional view, positive charges being present in a band-like distribution on a recording material 1, which has a photoconductive layer 11 and an electrically conductive carrier 12 includes. The sketch (b) shows the distribution of an electric field near the surface of the photoconductive layer in a direction perpendicular to the photoconductive layer, as in FIG. 1 (a). The horizontal axis represents the charge of the photoconductive layer and the vertical axis represents the strength of the electric field. As can be seen from Fig. 1 (b), a positive electric field (the direction perpendicular to <' ^r > outside of the surface of the photoconductive layer is defined as "positive") formed within an area where positive charges are present; however, the electric field distribution is not

uniform. The strength of the electric field within a part of the band (the hereinafter referred to as "tape"), where electrical charges are present, relatively low, near the ends of the ribbon at a maximum and practically zero at the ends of the ribbon. on the other hand If the electric field outside the ribbon is negative, its strength near the ends of the ribbon is at is a maximum, and becomes smaller away from the band. When a positively charged toner with the When the photoconductive layer is brought into contact, the toner will be in the negative areas of the attracted electric field. The development in the immediate vicinity of the end of the belt is very strong, while it decreases as the distance from the belt increases. This phenomenon is generally called "Edge effect" known.

To overcome this disadvantage, it is known to use a developing electrode. In the F i g. 2 (c) and (d) show the lines of electric force and the electric field distribution in this case. Here, Fig. 2 (c) shows that the lines of electric force are substantially perpendicular to the photoconductive layer when the developing electrode 2 is arranged practically in parallel in the vicinity of the photoconductive layer 11, while Fig. 2 (d) shows the state of distribution of the electric field this arrangement indicates. In this way a positive electric field of substantially uniform strength within the belt and a negative electric field outside the belt are obtained. Even if the gap between the developing electrode and the photoconductive layer can be reduced to a very small extent with the distribution of the positive electric field within the belt perpendicular and zero outside the belt, it is difficult to keep the gap beyond a certain extent to reduce, since in practice a toner is introduced into this gap. Therefore, touching a positive toner while leaving some space will result in poor adhesion of the toner to the outside of the belt. In order to effectively adhere a toner to areas outside the belt, it is known to be necessary to apply an external electric field as shown in FIG. In Fig. 3 (e), a voltage Va is applied across the voltage source 3 in order to compensate for the electric field of positive charges on the photoconductive layer.

As a result, the lines of electric force directed to the development electrode from the belt disappear, while the lines of electric force directed to the photoconductive layer of the development electrode appear outside the belt. Fig. 3 (f) shows the distribution of the electric field in this case, which is almost zero inside the band and has a substantially uniform negative value outside the band. When a positively charged toner is brought into contact with the photoconductive layer under such conditions, it adheres to the periphery of the belt in a substantially uniform and sufficient density, whereby the desired reversal development can be achieved. In this case, the applied voltage V ;; lower than the voltage required for compensation specified above. If Va just compensates for the electric field of the positive charges of the tape, Va is at the upper limit and wsnn Va is less than this value, a positive electric field is formed inside the tape and a negative electric field outside the tape. This negative electric field need only be of sufficient strength to cause a toner to adhere to the photoconductive layer.

In the explanation given above, the

in dark decay the photoconductive layer is disregarded. Since a conventional photoconductive layer exhibits a greater or lesser degree of dark decay, the electrical charges on the photoconductive layer decrease over time and the electric field decreases accordingly. F i g. 4 shows a graph of the decay of darkness of the photoconductive layer, in which the horizontal axis represents the time and the vertical axis represents the electric field in the vertical direction in the vicinity of the surface of the photoconductive layer. At the point in time ί = 0, the electrostatic charge of the photoconductive layer is at a maximum, the electric field at this point in time being E ₀ . E ₀ is the electric field in the size of the initial potential.

2 "> If the development is started at time t = T \ and is completed at time t = T ₂ , the electric field is reduced from E = E \ at t = 71 ■ to E - E ₂ at ί = T _2. Ei-E ₂ can range from a very large value to a very small value in

3D may vary according to the properties or characteristics of the photoconductive layer. In fact, the value of E ₁ -E ₂ varies from several volts to several thousand volts at times. If the development is carried out while an external j voltage Va \ is applied which compensates the electric field Ei at t = T \ , or which is slightly less than the required compensation voltage, the electric field formed by the external voltage exceeds that by the electric charges of the photoconductive layer generated electric field after a period of time t = Ti to ί = T _2, so that a toner adheres in this way to areas to which the toner was not originally adhered, thereby causing fogging. It was determined,

• i ") that this disadvantage can be overcome by the external voltage during development corresponding to the dark decay of the charge of the photoconductive layer changes, whereby both electric fields are each just compensated, or the

κι external tension is kept somewhat lower, or by previously considering the dark drop in voltage of the photoconductive layer during the Checks development and reduces external tension by at least the determined degree. Although

, ·, In the above illustration, the dark decay of the photoconductive layer is considered, the photoconductive layer in the case of execution a development with a liquid developer often influenced by the insulating carrier liquid,

μ ι whereby the voltage drops even faster. If the photoconductive layer consists of a mixture of zinc oxide powder and a resin, the Resin is a silicone resin, for example, the resin absorbs a variety of organic insulating liquids.

n'i th, even if it is not resolved in it, and the The voltage drop becomes so rapid that development cannot be performed. The initial potential for example on the order of 500 volts

sometimes almost zero after about 10 seconds when in contact with kerosene. While such waste can be reduced by changing the type of resin, many of the resins, e.g. B. hardened alkyd resins as associated with a particular drop of the potential by the ^r> contact with insulating fluids to a greater extent on standing in the air.

In the case of powder atomization development, development using a magnetic brush or cascade development, it is only necessary to reduce the charge drop in Air should be taken into account, whereas in the case of liquid development the potential drop through a Fluid mostly has to be taken into account.

FIG. 5 shows the charge drop in air and that in an insulating liquid, the former being represented by curve A and the latter by curve B. The photoconductive layer with an electric field on the surface of Eo at time t = 0 experiences a charge decrease along curve A in air, the decrease in surface potential progressing along curve B with the start of liquid development at time t = 71. When the development is interrupted at time t - Ti , the surface potential has decreased to Ε-ί. In air, this surface potential should be in the order of magnitude of Ej at the point in time f = 7 ~ 2. It has often been found that E _x -Ei <<E \ -Ei .

With the method according to the invention, it is now possible to change the external voltage in order to with w to be synchronous with the voltage drop of the photoconductive layer, and thereby in a constant manner applies a voltage that is sufficient to maximize an electric field of electric charges To compensate or reverse charge density on the photoconductive layer, or something lower tension than the compensation tensioning or a constant external tension which, taking into account the strength of the Decrease in the electric field during development in accordance with the behavior of the photoconductive layer and after subtraction of at least one corresponding to the electric field Voltage was calculated.

The foregoing is made with reference to an example in which electric charges a constant charge density are present on certain areas of a photoconductive layer and no electrical charges are present on other surfaces, however, since the charge density is zero is continuously distributed up to a maximum, according to the applied light image, it can be seen that in practical reverse development areas of maximum charge density correspond to the areas of a constant charge density in the explanation given above.

The method according to the invention enables the formation of toner images, if not none unwanted toner deposits due to dark decay of the photoconductive layer and thus clear images free from fog can be produced will.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Process for the reverse development of an electrostatic charge image on a photoconductive one Layer using a liquid developer, whereby by applying an outer Voltage on a development electrode the electric field in the range of the maximum charge density the photoconductive layer just compensated or with a somewhat lower appearance Voltage is applied to the developing electrode as the voltage required for compensation is characterized in that the external tension during development corresponding to the dark decay of the charge of those in contact with the liquid developer photoconductive layer changes. 2. The method according to claim 1, characterized in that the voltage change is continuous and executes synchronously with the dark decay. 3. The method according to claim 1, characterized in that the voltage change in one Jump.